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package org.bouncycastle.math.ec;

import java.math.BigInteger;

/**
 * Class implementing the WTNAF (Window
 * τ-adic Non-Adjacent Form) algorithm.
 */
class WTauNafMultiplier implements ECMultiplier
{
    /**
     * Multiplies a {@link org.bouncycastle.math.ec.ECPoint.F2m ECPoint.F2m}
     * by k using the reduced τ-adic NAF (RTNAF)
     * method.
     * @param p The ECPoint.F2m to multiply.
     * @param k The integer by which to multiply k.
     * @return p multiplied by k.
     */
    public ECPoint multiply(ECPoint point, BigInteger k, PreCompInfo preCompInfo)
    {
        if (!(point instanceof ECPoint.F2m))
        {
            throw new IllegalArgumentException("Only ECPoint.F2m can be " +
                    "used in WTauNafMultiplier");
        }

        ECPoint.F2m p = (ECPoint.F2m)point;

        ECCurve.F2m curve = (ECCurve.F2m) p.getCurve();
        int m = curve.getM();
        byte a = curve.getA().toBigInteger().byteValue();
        byte mu = curve.getMu();
        BigInteger[] s = curve.getSi();

        ZTauElement rho = Tnaf.partModReduction(k, m, a, s, mu, (byte)10);

        return multiplyWTnaf(p, rho, preCompInfo, a, mu);
    }

    /**
     * Multiplies a {@link org.bouncycastle.math.ec.ECPoint.F2m ECPoint.F2m}
     * by an element λ of Z[τ] using
     * the τ-adic NAF (TNAF) method.
     * @param p The ECPoint.F2m to multiply.
     * @param lambda The element λ of
     * Z[τ] of which to compute the
     * [τ]-adic NAF.
     * @return p multiplied by λ.
     */
    private ECPoint.F2m multiplyWTnaf(ECPoint.F2m p, ZTauElement lambda,
            PreCompInfo preCompInfo, byte a, byte mu)
    {
        ZTauElement[] alpha;
        if (a == 0)
        {
            alpha = Tnaf.alpha0;
        }
        else
        {
            // a == 1
            alpha = Tnaf.alpha1;
        }

        BigInteger tw = Tnaf.getTw(mu, Tnaf.WIDTH);

        byte[]u = Tnaf.tauAdicWNaf(mu, lambda, Tnaf.WIDTH,
                BigInteger.valueOf(Tnaf.POW_2_WIDTH), tw, alpha);

        return multiplyFromWTnaf(p, u, preCompInfo);
    }

    /**
     * Multiplies a {@link org.bouncycastle.math.ec.ECPoint.F2m ECPoint.F2m}
     * by an element λ of Z[τ]
     * using the window τ-adic NAF (TNAF) method, given the
     * WTNAF of λ.
     * @param p The ECPoint.F2m to multiply.
     * @param u The the WTNAF of λ..
     * @return λ * p
     */
    private static ECPoint.F2m multiplyFromWTnaf(ECPoint.F2m p, byte[] u,
            PreCompInfo preCompInfo)
    {
        ECCurve.F2m curve = (ECCurve.F2m)p.getCurve();
        byte a = curve.getA().toBigInteger().byteValue();

        ECPoint.F2m[] pu;
        if ((preCompInfo == null) || !(preCompInfo instanceof WTauNafPreCompInfo))
        {
            pu = Tnaf.getPreComp(p, a);
            p.setPreCompInfo(new WTauNafPreCompInfo(pu));
        }
        else
        {
            pu = ((WTauNafPreCompInfo)preCompInfo).getPreComp();
        }

        // q = infinity
        ECPoint.F2m q = (ECPoint.F2m) p.getCurve().getInfinity();
        for (int i = u.length - 1; i >= 0; i--)
        {
            q = Tnaf.tau(q);
            if (u[i] != 0)
            {
                if (u[i] > 0)
                {
                    q = q.addSimple(pu[u[i]]);
                }
                else
                {
                    // u[i] < 0
                    q = q.subtractSimple(pu[-u[i]]);
                }
            }
        }

        return q;
    }
}




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